NO170189B - DEVICE FOR AA ESTABLISH BROADBAND CONNECTION IN A SWITCH NETWORK - Google Patents

Description

TECHNICAL AREA

The present invention relates to a device for establishing a broadband connection in a switching network in telecommunications equipment which is operated with pulse code modulation and time division multiplexing, the connection comprising two or more channels.

STATE OF THE ART

The present invention is intended to be used in connection with telecommunication systems which divide the bit stream into a plurality of channels for a predetermined number of bits, e.g. channels with 64 kbit, which applies e.g. for AX type system.

With such systems, there is a need to enable the establishment of high-quality connections, e.g. video transmission connections. This means, among other things, that a sampling rate must be able to be used, which is higher than that which applies to the basic system.

The problem is solved by means of two or more channels which are combined and thus provide a so-called broadband connection. Such channels that form a broadband connection must be monitored when establishing communication in the switching network, so that respective content/samplings do not delay each other, because there is distortion in the transmitted information, if this delay takes place.

To solve this problem, it would be possible to modify the group selector (switching network) in the respective station/switchboard, where this modification would mean that the selection of internal time slots must be controlled for the broadband connection.

In this connection, the time slots had to be selected so that writing/reading from the voice stores for the channels that are included in the connection is carried out with the information combined. Such a modification can be carried out completely in the software.

ACCOUNT OF THE INVENTION

The solution proposed above, however, involves major disadvantages, because the internal time slots are not freely available, which causes the likelihood of accumulation or blocking. The probability of accumulation also seems to depend on the relationship between incoming and outgoing time slots. The increased probability of congestion will thus extend the average connection time.

An alternative way of solving the aforementioned problem is that when local or transit nodes are connected, a possible mutual delay due to the transfer between inner and outer time slots is allowed, and to equalize the possible delay between the contents of the channels after a pass-through has been performed in the switching network.

The invention tackles this problem, and proposes that during a connection phase the input to the switching network is supplied with special information with regard to the respective phase position of the channel content, and that at the output from the network this special information is detected, and the delays are regulated in bodies for equalizing the content of the channels.

What can more concretely be regarded as characteristic of the new device is that a marking means is placed in the entrance to the switching network, so that, during a connection establishment step, the means provides markings in a plurality of successive frames of the respective content in the time slots used by the channels of the connection, and that the marking means adds a first marking to the contents of the affected time slot in a first frame and a second marking to the contents of each affected time slot in a second frame, etc., until the number of such successive frames is equal to a maximum time shift in the switching network, while the displacement corresponds to a number of frames plus a constant, and that a sensing device is arranged at the output of the switching network, so that the sensing device detects a pattern formed by said markings, and with the help of said pattern confirms a possible delay between the respective contents of the channels due to through the switching process in the switching circuit, and that the scanning means controls a means that equalizes delays in the channels, so that it is ensured that, after the connection establishment step, the contents of the channels/time slots regain their mutually synchronized positions despite the possible mutual delay.

In a preferred embodiment, the device is characterized in that the number of frames corresponding to the maximum displacement in the switching network plus said constant forms a first group of frames which is followed by a corresponding second group of frames, etc.

Furthermore, it has been confirmed that the marking body attributes the content of influencing time slots to the same marking in different groups of frames.

Using the device according to the invention, broadband connections can be established without the respective group selector/switching network needing to be modified for the connection in question. The equipment required for marking, detecting the marking and establishing the connection can be attributed to broadband connections as such, which can be advantageous for determining the cost carriers in the system.

BRIEF DESCRIPTION OF THE DRAWING FIGURES.

A current embodiment of a device that includes the characteristic features of the invention will now be discussed in the following with reference to the attached drawings. Figure 1 is a principle sketch of the marking of the content of the channel/time slots in a number of consecutive frames. Figure 2 is a table (a pattern) of the marking of the frames and channels on the input side of a switching network/group selector. Figure 2a is a table (a pattern) of the marking of the frames and channels on the output side from the switching network/group selector. Figure 3 is a schematic diagram showing the bodies which carry out the markings, arranged at the entrance to the switching network/group selector. Figure 4 shows detection means for detecting the markings and connections in the channels.

EMBODIMENTS OF THE INVENTION.

The invention is intended to be used for through connections

in connection with broadband connections in group selectors or similar units that are connected to communication equipment that works with pulse code modulation and time division multiplexing. The telecommunications equipment can be of the AX type, which divides the bit stream into channels of 64 kbit with a sampling frequency of 8000 samp-

ler/second with 8 bits in 256 bit frames.

Figure 1 shows six successively arranged frames 0-5 in series one after the other in a connection not shown in the figure

see with a group selector or similar device.

According to the invention, the content of the time slots that are used as a channel in the broadband connection will be marked on the input side of the group selector. In this embodiment, it is assumed that three channels are incorporated into a broadband connection. Three of these time slots used in these three channels are marked with a, b, c in a first group of frames A and with a', b<1> and c<1> in another group B.

The respective three time slots in respective frames 0-5 are

shown next to each other, although the time slots may be scattered within the respective frame.

The time slots a in frame 0 are marked exactly the same, and in the present case the marking consists of the binary value 0

which is shown with the numerical value 0 in Figure 1 for simplicity. Time slot b in frame 1 is marked in a similar way with the binary value 1, and time slot c in frame 2 with the binary value 2.

The time slots a' in frame 3 are marked exactly the same, and the marking but 0. The time slot b' in frame 4 is marked as the time slot b in frame 1 and the time slot c' in frame 5 as the time slot c in frame 2.

The number of individual markings, i.e. the number of frames in the respective groups A, B is dependent on the maximum difference in time shift that can occur in the group selector (switching network) calculated in a number of frames. The number of individual markings is thus equal to the maximum offset plus a constant 2. Because the content of the three channels in the AX type system must be mutually delayed by at least one frame, a plurality of individual markings is obtained, which in the present case will be 3.

The number of groups A, B depends on how long it takes to determine the mutual difference. The groups of frames that follow group B in figure 1 have a similar structure and marking as groups A and B. Figure 2 shows in the form of a table the marking/pattern according to figure 1, i.e. how the marking appears on the input side of the group selector . In the table, the frames have designations corresponding to the frames in figure 1. The channels that use the time slots in a, b, c etc. have been designated by 0', l', 2' in the table. Figure 2a shows how the content of channel 1<1> is delayed compared to the content of channels 0<1> and 2'. The delay here is dependent on the connection between the outer and inner time slots in connection with switching in the group selector. This means that the contents of the channel are 0' and 2'

must be delayed by a frame length before the bit stream is forwarded to the outgoing line.

According to Figure 3, the bit stream will come from the line

L. Marking of the contents of the respective channel/time slots takes place using a pattern generator M and a selector VI which can be controlled using the control unit S. The selector VI connects the line L to the group selector

G via L', and in response to orders from the control unit it can temporarily connect the pattern generator for marking the contents of the respective affected time slots.

The control unit includes a storage m, in which the prerequisites for the control unit's operating mode are written from an unshown superior unit. The writing takes place via a LED 1^ and addressing to the various cells (0-31) using a selector device V2 which is controlled via ±2• There are two control orders: Order 1 "take from the line" and order II,

"get pattern".

The control order stored in the storage m is read by means of a channel counter K which counts between 0-31 and is controlled by a 256-kHz signal via I3 and a synchronization signal of 8 kHz via the line I4. A current reading from the storage m is carried out using the selector device V3.

The pattern generator M includes the register RI, R2 and R3, the outputs of which are connected to an OR gate OR, which has an output connected to position 2 of the selector device VI. The respective register provides the markings 0, 1 and 2 in binary form.

The respective register has two control inputs sti and st2. The first input is controlled by a counter CNT which, in reaction to the control from the frame synchronization of 8 kHz via st3, activates the respective register. The control input st2 obtains a clock pulse of 256 kHz from a clock pulse source in the telecommunications equipment, and the control input St2' obtains a clock pulse of 2048 kHz from the same source.

Figure 4 shows a reading device AO which detects a pattern created by said marking, and with the help of the pattern it determines any delay between the contents of the channels.

The body AO includes a control part SD, a detection part DE, a selection body V4 and a storage ml, to which the orders from the superior unit are written, these orders being supplied to the selector body V4. The latter has two command positions: position 3 which constitutes a normal position, and position 4 which constitutes a position for analyzing delayed time slots (channels).

Writing to the storage ml takes place via a line lg and addressing to the cells 0-31 via a line I7. Time slot management is obtained from the superior unit. Reading from the storage ml is controlled from the channel counter Kl via the lines 13', 14' in a similar way as the storage m is controlled from the channel counter K. Reading from the storage ml for controlling the selector device V4 takes place via a selector device V4' and a line 18-

The detection part comprises a plurality of identically executed parts

are part<1>, part<11>, part<1>'<1>, the number of these corresponding to the number of used patterns.

The individual part includes a comparator KO. The output of the individual comparator is connected to an AND post AND, and its other input is connected to an inverting device I which is loop-connected from the output of an AND gate. Furthermore, a register REG is incorporated there, with an output which is connected to its respective storage SO, Sl or S2. The respective output from the AND gate AND is connected to both the register REG and a flip-flop V. An input to the respective register REG is also connected to the output from the channel counter Kl.

Each of the similarly designed parts is designed to react

on its individual marking. Consequently, part' will respond to mark 0, part1 1 to mark 1 and part111 to mark 2.

The output of the respective flip-flop V in part' and part'' is connected to an AND gate & 0, the output of the respective flip-flop V in part<1>.' and part<1>'<1> to an AND gate & 1, and the output of the respective flip-flop from part''' and part' to an AND gate & 2.

According to the example shown in Figure 2a, a pattern 0.2.0 is obtained from the desired frame. The comparator KO in part<1> reacts to the marking 0 in time slot zero, which results in the flip-flop V in part<1> being set, and the channel address for the relevant time slot being written into (stored in) the storage SO. The comparator in part<1>'<1> responds to the mark 2 in time slot 1, which results in flip-flop V being set in part''<1>, and the channel address for the relevant time slot being written into (stored in) the memory S2. What has just been said means that the AND gate & 2 sets its output to a one. The comparator in part' responds to the zero mark in time slot 2, and the channel address for this time slot is also written into (stored in) memory SO.

A first order or instruction is thus issued from the outputs of AND gates &o, &1 and &2. A different ON setting of the AND gate outputs results in different output instructions, etc.

Figure 4 also shows an organ UO which equalizes delays in affected channels. The device UO includes a storage Ml which receives instructions from the device AO. These instructions in the store M1 are read out by means of the selector device V5, which is controlled by a channel counter K2 which in turn is controlled in a similar way to the channel counter K via the lines 13'' and I4''•

The organ UO includes selection organs V6 with order positions D and D. The line coming from the group selector is denoted by LI in the figure. The selector device V4 will normally direct the bit stream to the line L2, but in the cases where marked channels are to be identified against the line L3, it directs the bit stream to the said detection device

gan AO.

The line L2 branches out into two line paths L2' and L2". A register RE comprising a register of 256 bits of a known type is linked into the line part L2<1.> The selector element V6 connects the line L3 to one of the paths L2' and L2 ", determined by the body UO.

The instruction from the output A01 formed in the device AO is transferred to the storage Ml (input U01) in a known manner, e.g. using a known control system. According to the above, the instructions indicated below are written into the storage Ml, in response to what was obtained at the outputs AOi (the outputs & 0-&

2 from the AND gates).

If all AND gates &0 - & 2 are reset, the order D (no delay) will be written into the storage Ml for all the affected channels, whose addresses are written/stored in SO, Sl or S2. If the gate & 0 is set to a one, D is written into the store Ml for all channels that have addresses registered in the store Sl, and D for all channels with addresses registered in the store SO. If the gate & 1 is set to a one, D is written into the store Ml for all channels with addresses written into the store S2,

and D for all channels with addresses written in the warehouse Sl. Finally, when only the &2 gate is set to a one, the order D is written into memory M1 for all channels with addresses written into memory SO, and D for all channels with addresses written into memory S2.

From the above, it will be seen that what is delayed is only the content of the respective channel incorporated in the broadband connection, because the content of the other time slots in the respective frames is shunted via the command position D.

After providing instructions to the storage Ml, the broadband connection is established, and subsequent frames will be fed into the line paths determined by the storage Ml past and/or through the delay register RE which delays the bit stream controlled via the line path L2' by a frame length.

The equipment described above can be suitably incorporated into the terminal equipment in connection with group selection networks. The terminal equipment is duplicated in the case where two-way paths are established through the switching network.

The invention is not limited to what is described above and exemplified by the embodiment, but can be subjected to modifications within the scope of the following claims and the idea behind the embodiment.

Claims (7)

1. Device for establishing a broadband connection in a switching network (G) in telecommunications equipment operated with pulse code modulation and time division multiplexing, the connection comprising two or more channels, characterized in that a marking device (M) is placed in the entrance to the switching network, so that, during a connection establishment step, the device provides markings in a plurality of successive frames of the respective content in the time slots utilized by the channels of the connection, and the demarking means adds a first mark to the contents of the affected time slot in a first frame, a second mark to the contents of each affected time slot in a second frame, etc., until the number of such successive frames equals a maximum time offset in the switching network, while the displacement corresponds to a number of frames plus a constant, and that a sensing element (AO) is arranged at the output of the switching network, so that the sensing element detects a pattern formed by said markings, and with the help of said pattern confirms any delay between the respective contents of the channels due to the switching process in the switching circuit, and that the scanning means (AO) controls a means (UO) which equalizes delays in the channels, so as to ensure that, after the connection establishment step, the contents of the channels/timeslots regain their mutually synchronized positions despite the eventual mutual delay. 2. Device as stated in claim 1, characterized in that the number of the frame corresponding to the maximum displacement in the switching network plus said constant, forms a first group (A) of frames which is followed by a corresponding second group (B) of frames, etc. 3. Device as stated in claim 1, characterized in that the marking device (M) assigns the content of affected time slots the same marking in different groups of frames. 4. Device as stated in claim 1, characterized in that the weaning body includes a comparison body (KO) which compares the respective frames, the comparison means (KO) being adapted to, in response to the comparison, feed instructions to a store (Ml) incorporated in the equalization means (UO). 5. Device as stated in claim 4, characterized in that the equalization means (UO) includes two or more parallel paths (L2', L211) for the bit stream, the first (L2'<1>) delay and the second (L2<1>) delays the bit stream by a frame length, etc., and that the equalizer (UO) is arranged to feed the channel contents to different lanes (L2<1>, L2<11>) in response to said instructions. 6. Device as specified in claim 1, characterized in that the sensing element (AO) includes parts (part' part<*>', part<1>,<1>) which are assigned their respective individual markings, and that the parts control a gate network (&0-&2), and that instructions to the equalizer (UO) are provided at the outputs of the gate network. 7. Device as stated in claim 6, characterized in that the instructions on the outputs of the port network can be suitably transferred to a store (Ml) in the equalization device (UO) together with the channel addresses, which, when detected, are stored in stores (SO, Sl, S2) included in the respective parts (part', part<11>, part'<11>).